Projection type video display

ABSTRACT

There are provided a write light valve for generating image-writing light by modulating write light, a driver for writing images into the write light valve based on image data, read light valves for each color for generating respective color image lights by modulating each received color illumination light, an imaging lens group for guiding the image-writing light emitted from the write light valve to the respective read light valves, a dichroic cube for combining together color image lights emitted from the respective read light valves, a projection lens for projecting each color image light combined together. The imaging lens group has a distortion aberration which reduces or cancels out a distortion aberration of the projection lens.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is based upon and the benefit of priority from prior Japanese Patent Applications No.2006-051323, No.2006-051324, No.2006-051325 and No.2006-051326 filed on Feb. 27, 2006, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a projection type video display in which an image writing to a read light valve that generates projection image light is performed by using light.

2. Description of the Related Art

A projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light is known (refer to a pamphlet of International Laid-Open WO 2005/116719 and Japanese Unexamined Patent Publication No. 2004-94115, for example). As an example, a conventional projection type video display is shown in FIG. 1. White light emitted from a white light source 101 is converted to substantially parallel light by a parabolic reflector, and the parallel light is introduced into an integrator lens 102. The integrator lens 102 is constructed by a pair of fly's eye lenses 102 a and 102 b and each of the pairs of lens parts leading light emitted from the white light source 101 to the whole surfaces of a read light valve described later. Light that has passed through the integrator lens 102 is introduced into a first dichroic mirror 105 after passing through a polarization converter 103 and collective lens 104.

The polarization converter 103 is constructed by a polarization beam splitter array (hereinbelow, referred to as PBS array). Each of the PBSs has polarization separation films and a retardation film (½λ plate). Each of the polarization separation films in the PBS transmits, for example, P-polarized light in light from the integrator lens 102 and changes the optical path of S-polarized light by 90°. The S-polarized light whose optical path is changed is reflected by the adjoining polarization film and goes out as it is. On the other hand, the P-polarized light which has passed through the polarization separation film provided on the front side (light-exit side) of the PBS is converted to S-polarized light by the retardation film and the S-polarized light goes out. That is, in this case, substantially all of light is converted to S-polarized light.

A first dichroic mirror 105 transmits first color light while reflecting second color light and third color light. The first color light which has passed through the first dichroic mirror 105 is reflected by a tilted reflecting mirror 106. The first color light reflected by the tilted reflecting mirror 106 is introduced into a transmission-type read light valve 131 for first color light via a lens 107. The first color light changes to first color image light as a result of passing through the read light valve 131. On the other hand, light reflected by the first dichroic mirror 105 is introduced into a second dichroic mirror 108.

The second dichroic mirror 108 transmits third color light while reflecting second color light. The second color light reflected by the second dichroic mirror 108 is introduced into a transmission-type read light valve 132 for second color light via a lens 109. The second color light changes to second color image light as a result of passing through the read light valve 132.

A first dichroic cube 112 is provided at a position where an optical path of the first color image light and an optical path of the second color image light are crossed. The first dichroic cube 112 transmits the first color light while reflecting the second color light. The first color image light and the second color image light are incident on the first dichroic cube 112, directing them to the same direction.

The third color light which has passed through the second dichroic mirror 108 is introduced into a transmission-type read light valve 133 for third color light via a lens 110. The third color light changes to third color image light as a result of passing through the read light valve 133. An optical path of the third color image light is changed by 90° by a reflecting prism 111.

A second dichroic cube 113 is provided at a position where a changed optical path of the third color image light and an optical path which is combined the optical path of the first color image light with the optical path of the second color image light are crossed. The second dichroic cube 113 transmits the first color light and the second color light while reflecting the third color light. The first color image light, the second color image light and the third color image light are incident on the second dichroic cube 113, directing them to the same direction. This generates full-color image light.

At the light exit side of the second dichroic cube 113 (beside a surface which emits the full-color image light), there is disposed a projection lens 114. The full-color image light emitted from the second dichroic cube 113 is projected onto a not-shown screen through the projection lens 114.

Next, an image writing optical system will be described hereinafter. The image writing optical system includes three UV (Ultraviolet)-LEDs (light-emitting diode) 121A, 121B and 121C. The peak wavelength of UV-LEDs 121A, 121B and 121C are different from one another. UV-LEDs 121A, 121B and 121C are turned on in a time-sequential manner. UV lights emitted from UV-LEDs 121A, 121B and 121C are directed to the same direction by dichroic mirrors 120A, 120B. When UV lights pass through a rod integrator 122, a surface illuminant with uniform light intensity is formed at the exit surface of the rod integrator 122. UV lights emitted from the exit surface are introduced into a polarization beam splitter 124 after passing through a relay lens group 123.

Particular polarized light (for example, P-polarized light) which has passed through the polarization beam splitter 124 is introduced into a write light valve (for example, LCOS (liquid-crystal-on-silicon) device) 125 which modulates write light (said UV light). The write light valve 125 generates images for respective colors in a time-sequential manner by a not-shown driver. That is, the driver writes a first image into the write light valve 125 based on a first color video signal when UV-LED 121A is turned on, next writes a second image into the write light valve 125 based on a second color video signal when UV-LED 121B is turned on, and writes a third image into the write light valve 125 based on a third color video signal when UV-LED 121C is turned on, for example.

The write light valve 125 generates image light by modulating the received particular polarized light. The image light is obtained as reflected light, and the reflected light is changed to the other particular polarized light (for example, S-polarized light). That is, when the particular polarized light is irradiated on the write light valve 125, image-writing light having the other particular polarized light (S-polarized light) is generated. The image-writing light emitted from the write light valve 125 is reflected on the polarization beam splitter 124. The image-writing light is introduced into the second dichroic cube 113 through an imaging lens group 126.

Each of the second dichroic cube 113 and the first dichroic cube 112 has wavelength selectivity in UV lights from UV-LEDs 121A, 121B and 121C. Three UV lights having different peak-wavelengths from one another are split, and each split light (the aforementioned image-writing light) is introduced into the respective read light valves 131, 132 and 133. Specifically, first image-writing light based on the first color video signal is irradiated on the read light valve 131, second image-writing light based on the second color video signal is irradiated on the read light valve 132, and third image-writing light based on the third color video signal is irradiated on the read light valve 133.

As disclosed in the pamphlet of International Laid-Open WO 2005/116719, each of the read light valves 131, 132 and 133 is composed of an OASLM (Optically Addressed Spatial Light Modulator) having a photoconductive effect. For example, with a configuration in which liquid crystal layer is interposed between optically transparent electrode structures having a photoconductive effect, a change of photoconductive effect occurs in only a portion where light is irradiated, with the result that a change of a voltage applying state to the liquid crystal occurs in said portion where light is irradiated, changing a state of rotation of the liquid crystal.

The conventional projection type video display described above, particularly the projection type video display shown in FIG. 1, however, needs a large projection lens having a long back focal length. In a case where the projection lens is particularly designed in wide-angle lens specifications, there is the drawback that a distortion aberration is likely to occur. Further, in a case where a chromatic aberration of magnification occurs in a projection optical system, a color blur may occur in a projected image on a screen.

SUMMARY OF THE INVENTION

A purpose of the present invention is to provide a projection type video display which enables to reduce inconvenience due to an optical cause, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light.

A projection type video display according to the present invention includes: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; read light valves for each color, in which an image is written by the image-writing light emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the respective read light valves; means for combining together color image lights emitted from the respective read light valves; and a projection optical system for projecting each color image light combined together, wherein the writing optical system has a distortion aberration which reduces or cancels out a distortion aberration of the projection optical system.

With the aforementioned projection type video display, since the writing optical system has the distortion aberration which reduces or cancels out the distortion aberration of the projection optical system, the projection image whose distortion is reduced is obtained, even if in a case where the distortion aberration is likely to occur due to the necessity of providing a large projection lens having long back focal length and also because the projection lens is particularly designed with wide-angle lens specifications.

In the projection type video display, a pincushion distortion may occur in the projection image projected through the projection optical system, and a barrel distortion may occur in the image-writing light in the writing optical system. Or, in the projection type video display, a barrel distortion may occur in the projection image projected through the projection optical system, and a pincushion distortion may occur in the image-writing light in the writing optical system.

A projection type video display according to the present invention includes: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; read light valves for each color, in which an image is written by the image-writing light emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the respective read light valves; means for combining together color image lights emitted from the respective read light valves; and a projection optical system for projecting each color image light combined together, wherein sizes of written images on the respective read light valves are different from one another due to the write lights having different peak-wavelengths, with the result that a difference in size of each color projected image on a screen is reduced due to the occurrence of a chromatic aberration of magnification in the projection optical system.

With the aforementioned projection type video display, since the sizes of written images on the respective read light valves are different from one another due to the write lights having different peak-wavelengths, with the result that the difference in size of each color projected image on the screen is reduced due to the occurrence of the chromatic aberration of magnification in the projection optical system. Therefore, the color blur in the projected image on the screen is reduced, even if in a case where the chromatic aberration of magnification occurs in the projection optical system. Further, a difficulty in a design for a reduction of the chromatic aberration of magnification needed in the projection optical system is also reduced.

In the aforementioned projection type video display, it may be configured such that on the condition that a peak-wavelength of each write light is denoted by λ1, λ2, λ3 (λ1>λ2>λ3) and a wavelength of each color illumination light is denoted by λ11, λ12, λ13 (λ11<λ12<λ13), an image writing using the write light with wavelength λ1 is performed when the color illumination light with wavelength λ11 is incident on the read light valve, an image writing using the write light with wavelength λ2 is performed when the color illumination light with wavelength λ12 is incident on the read light valve, and an image writing using the write light with wavelength λ3 is performed when the color illumination light with wavelength λ13 is incident on the read light valve.

It is preferable that the aforementioned driver adjusts a position of the image for each color which is written into the write light valve based on a given position adjustment amount. With the projection type video display having the aforementioned driver, since the position of the image for each color which is written into the write light valve is adjusted by the aforementioned driver, an adjustment of convergence is enabled, even if a shift of the position and a shift of the attitude of the elements which compose the optical system occur.

It is preferable that the aforementioned driver adjusts the size of the image for each color which is written into the write light valve based on a given size adjustment amount. With the projection type video display having the aforementioned driver, since the size of the image for each color which is written into the write light valve is adjusted by the aforementioned driver, a color blur occurred in the projected image on a screen is reduced, even if in a case where a chromatic aberration of magnification occurs in the projection optical system. Further, a difficulty in a design for a reduction of the chromatic aberration of magnification needed in the projection optical system is also reduced.

In the projection type video display, it is preferable that there is provided a shift device for shifting the write light valve or the writing optical system up-and-down and/or right-and-left in a plane perpendicular to an optical axis of the image writing. With the projection type video display having the aforementioned shift device, the write light valve or the writing optical system is shifted up-and-down and/or right-and-left in the plane perpendicular to the optical axis of the image-writing, thereby obtaining a mechanism which shifts the projection image without moving the body of the display, without increasing in size, weight and cost of the display.

In the projection type video display, it is preferable that there is further provided a shift instruction operation portion which inputs a signal indicating a shift by an user operation, wherein the aforementioned driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift. With the projection type video display having the aforementioned driver, the driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift, thereby obtaining a mechanism which shifts the projection image without moving the body of the display, without increasing in size, weight and cost of the display.

A projection type video display according to the present invention includes: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; a single read light valve, in which images are written by the image-writing lights emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the read light valve; and a projection optical system for projecting the image light emitted from the read light valve, wherein the writing optical system has a distortion aberration which reduces or cancels out a distortion aberration of the projection optical system.

With the aforementioned projection type video display, a configuration using a single transmission-type read light valve is realized. Further, since the writing optical system has a distortion aberration which reduces or cancels out a distortion aberration of the projection optical system, a projected image whose distortion is reduced is obtained, even if in a case where the distortion aberration is likely to occur due to necessity of a large projection lens having long back focal length and also because the projection lens is particularly designed with wide-angle lens specifications.

A projection type video display according to the present invention includes: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; a single read light valve, in which images are written by the image-writing lights emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the read light valve; and a projection optical system for projecting each color image light emitted from the read light valve, wherein the sizes of written images on the read light valve are different from one another due to the write light having different peak-wavelengths, with the result that a difference in size of each color projected image on a screen is reduced due to the occurrence of the chromatic aberration of magnification in the projection optical system.

With the aforementioned projection type video display, a configuration using a single transmission-type read light valve is realized. Further, the sizes of written images on the read light valve are different from one another due to the write lights having different peak-wavelengths, with the result that a difference in size of each color projected image on a screen is reduced due to the occurrence of a chromatic aberration of magnification in the projection optical system, thereby reducing a color blur in the projected image on a screen, even if in a case where a chromatic aberration of magnification occurs in the projection optical system. Further, a difficulty in a design for a reduction of the chromatic aberration of magnification needed in the projection optical system is also reduced.

In the aforementioned projection type video display, it may be configured such that on the condition that a peak-wavelength of each write light is denoted by λ1, λ2, λ3 (λ1>λ2>λ3) and a wavelength of each color illumination light is denoted by λ11, λ12, λ13 (λ1<λ12<λ13), an image writing using the write light with wavelength λ1 is performed when the color illumination light with wavelength λ11 is incident on the read light valve, an image writing using the write light with wavelength λ2 is performed when the color illumination light with wavelength λ12 is incident on the read light valve, and an image writing using the write light with wavelength λ3 is performed when the color illumination light with wavelength λ13 is incident on the read light valve.

In the projection type video display having the aforementioned single read light valve, there may be further provided a polarization beam splitter and an optical member for introducing the image-writing light emitted from the write light valve to the read light valve and for introducing each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the polarization beam splitter, and the image-writing light is changed into the particular polarized light, and the image-writing light is returned to the polarization beam splitter, and the returned image-writing light is reflected on the polarization beam splitter and is introduced into the optical member after passing through the writing optical system.

In the projection type video display having the aforementioned single read light valve, it is preferable that there is further provided an optical member for introducing the image-writing light emitted from the write light valve to the read light valve and for introducing each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the optical member and the writing optical system, and the image-writing light is introduced into the read light valve after passing through the writing optical system and the optical member. With the aforementioned projection type video display, it is possible to eliminate the polarization beam splitter.

In the projection type video display having the aforementioned single read light valve, it is preferable that there is further provided an optical member for leading the image-writing light emitted from the write light valve to the read light valve and for leading each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the optical member, and the image-writing light emitted from the write light valve introduced into the read light valve through the writing optical system after changing its optical path by the optical member, and each color image light is introduced into the projection optical system after passing through the writing optical system and the optical member, wherein an image formation plane of each color image light is formed between the projection optical system and the optical member. With the aforementioned projection type video display, since the image formation plane of each color image light is formed between the projection optical system and the optical member, it is possible to use a small-size projection lens whose back focus is shortened as the projection optical system.

In the projection type video display having the aforementioned single read light valve, it is preferable that there is provided a shift device for shifting the write light valve or the writing optical system up-and-down and/or right-and-left in a plane perpendicular to an optical axis of the image-writing. With the projection type video display having the aforementioned shift device, the write light valve or the writing optical system is shifted up-and-down and/or right-and-left in the plane perpendicular to the optical axis of the image-writing, thereby obtaining a mechanism which shifts the projection image without moving the body of the display, without increasing in size, weight and cost of the display.

In the projection type video display having the aforementioned single read light valve, it is preferable that there is further provided a shift instruction operation portion which inputs a signal indicating a shift by an user operation, wherein the aforementioned driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift. With the projection type video display having the aforementioned driver, the driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift, thereby obtaining a mechanism which shifts the projection image without moving the body of the display, without increasing in size, weight and cost of the display.

As described above, with the present invention, it is possible to provide a projection type video display which enables to reduce inconvenience due to an optical cause, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light.

The above and other objects, features, modes, and advantages of the present invention will become clear from the following detailed description with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanation view illustrating an optical system in a projection type video display according to a conventional projection type video display;

FIG. 2 is an explanation view illustrating an optical system in a projection type video display according to an embodiment of the present invention;

FIG. 3A is an explanation view showing a situation where a quadrangle shape image written into a write light valve is written into read light valves, and the written images by using light on these read light valves are projected on a screen;

FIG. 3B is an explanation view showing the same situation in a conventional projection type video display, for comparison purposes;

FIG. 4A is an explanation view showing a situation where written images by using light on read light valves are projected;

FIG. 4B is an explanation view showing the same situation in a conventional projection type video display, for comparison purposes;

FIG. 5 is an explanation view showing a configuration having an image formation optical system in the configuration of FIG. 2;

FIG. 6 is an explanation view showing another example of a configuration having an image formation optical system;

FIG. 7 is an explanation view showing another example of a configuration having an image formation optical system;

FIG. 8 is an explanation view illustrating a single-panel type projection type video display according to an embodiment of the present invention;

FIG. 9 is an explanation view illustrating an optical system in a single-panel type projection type video display according to another example of an embodiment of the present invention;

FIG. 10 is an explanation view illustrating an optical system in a single-panel type projection type video display according to another example of an embodiment of the present invention;

FIG. 11 is an explanation view illustrating an light source capable of using a projection type video display according to the present invention;

FIG. 12A is an explanation view showing a situation where quadrangle shape images written into a write light valve are written into read light valves, and each written image by using light on read light valves are projected on the same position on a screen;

FIG. 12B is an explanation view showing the same situation in a conventional projection type video display, for comparison purposes;

FIG. 13A is an explanation view showing a situation where written images using light on read light valves are projected on a screen;

FIG. 13B is an explanation view showing the same situation in a conventional projection type video display, for comparison purposes;

FIG. 14A is an explanation view showing a situation where a barrel shape image written into a write light valve is written into read light valves, and the written image (the barrel shape) using light is projected in a quadrangle shape on a screen;

FIG. 14B is an explanation view showing the same situation in a conventional projection type video display, for comparison purposes;

FIG. 15 is a perspective view illustrating a conventional lens shift device;

FIG. 16 is a view showing an embodiment of the present invention and an explanation view showing an optical path changing, in a simplified optical system, in a case where a write light valve is shifted;

FIG. 17 is a view showing an embodiment of the present invention and an explanation view showing an optical path changing, in a simplified optical system, in a case where an imaging lens group is shifted;

FIG. 18 is a view showing an embodiment of the present invention, and a perspective view showing a writing optical system;

FIG. 19A is a view showing an embodiment of the present invention and a cross-sectional view showing a shift device of a write light valve;

FIG. 19B is a front view thereof; and

FIG. 20 is a view showing an embodiment of the present invention and a perspective view showing writing optical system.

DETAILED DESCRIPTION OF THE EMBODIMENTS (Configuration of a Projection Type Video Display of an Embodiment)

Hereinafter, with reference to FIGS. 2 to 20, an embodiment of a projection type video display (projector) 50 of the present invention will be described.

FIG. 2 shows a projection type video display of this embodiment. White light emitted from a white light source 1 is converted to substantially parallel light by a parabolic reflector, and the parallel light is introduced into an integrator lens 2. The integrator lens 2 is constructed by a pair of fly's eye lenses 2 a, 2 b and each of the pairs of lens parts introducing light emitted from the white light source 1 to the whole surfaces of a read light valve described later. Light which goes out via the integrator lens 2 is introduced into a first dichroic mirror 5 after passing through a polarization converter 3 and a collective lens 4.

The polarization converter 3 is constructed by a polarization beam splitter array (hereinbelow, referred to as PBS array). Each of the PBSs has polarization separation films and a retardation film (½λ plate). Each of the polarization separation films in the PBS transmits, for example, P-polarized light in light from the integrator lens 2 and changes the optical path of S-polarized light by 90°. The S-polarized light whose optical path is changed is reflected by the adjoining polarization film and goes out as it is. On the other hand, the P-polarized light which has passed through the polarization separation film is converted to an S-polarized light by the retardation film provided on the front side (light-exit side) of the PBS is converted to S-polarized light by the retardation film and the S-polarized light goes out. That is, in this case, substantially all of light is converted to S-polarized light.

A first dichroic mirror 5 transmits blue color light while reflecting green color light and red color light. The blue color light which has passed through the first dichroic mirror 5 is reflected by a tilted reflecting mirror 6. The blue color light reflected on the tilted reflecting mirror 6 is introduced into a transmission-type read light valve 31 for blue color light via a lens 7. The blue color light changes to blue color image light as a result of passing through the read light valve 31. On the other hand, light reflected by the first dichroic mirror 5 is introduced into a second dichroic mirror 8.

The second dichroic mirror 8 transmits red color light while reflecting green color light. The green color light reflected on the second dichroic mirror 8 is introduced into a transmission-type read light valve 32 for green light via a lens 9. The green color light changes to green color image light as a result of passing through the read light valve 32.

A first dichroic cube 12 is provided at a position where an optical path of the first color image light and an optical path of the second color image light are crossed. The first dichroic cube 12 transmits the blue color light while reflecting the green color light. The blue color image light and the green color image light are incident on the first dichroic cube 12, directing them to the same direction. This generates cyan color image light.

The red color light which has passed through the second dichroic mirror 8 is introduced into a transmission-type read light valve 33 for red color light via a lens 10. The red color light changes to red color image light as a result of passing through the read light valve 33. An optical path of the third color image light is changed by 90° through a reflecting prism 11.

A second dichroic cube 13 is provided at a position where a changed optical path of the red color image light and an optical path of the cyan color image light are crossed. The second dichroic cube 13 transmits the blue color light and the green color light while reflecting the red color light. The cyan color image light and the red color image light are incident on the second dichroic cube 13, directing them to the same direction. This generates full-color image light.

At the light exit side of the second dichroic cube 13 (beside the surface which emits the full-color image light), there is placed a projection lens 14. The full-color image light emitted from the second dichroic cube 13 is projected onto a not-shown screen through the projection lens 14.

Next, image writing optical system will be described hereinbelow. The image writing optical system includes three UV(Ultraviolet)-LEDs(light-emitting diode) 21A, 21B and 21C. The UV-LEDs 21A, 21B and 21C are different from one another in the peak wavelength (λ1>λ2>λ3). The UV-LEDs 21A, 21B and 21C are turned on in a time-sequential manner. The UV lights emitted from the UV-LEDs 21A, 21B and 21C are introduced into the same direction by dichroic mirrors 20A, 20B. When UV lights pass through a rod integrator 22, a surface illuminant with uniform light intensity is formed at the exit surface of the rod integrator 22. The UV lights emitted from the exit surface are introduced into a polarization beam splitter 24 after passing through a relay lens group 23.

Particular polarized light (for example, P-polarized light) which has passed through the polarization beam splitter 24 is directed to a write light valve (for example, LCOS (liquid-crystal-on-silicon) device) 25 which modulates write lights (said UV lights). The write light valve 25 generates images for respective colors in a time-sequential manner with a driver 70. That is, the driver 70 writes a blue image into the write light valve 25 based on a blue color video signal when the UV-LEDs 21A is turned on, writes a green image into the write light valve 25 based on a green color video signal when the UV-LEDs 21B is turned on, and writes a red image into the write light valve 25 based on a red color video signal when the UV-LEDs 21C is turned on, for example.

The write light valve 25 generates image light by modulating the received particular polarized light. The image light is obtained as reflected light, and the reflected light is changed into the other particular polarized light (for example, S-polarized light). That is, when the particular polarized light is provided on the write light valve 25, image-writing light having the other particular polarized light (S-polarized light) is generated. The image-writing light emitted from the write light valve 25 is reflected on the polarization beam splitter 24. The image-writing light is introduced into the second dichroic cube 13 through an imaging lens group 26.

The second dichroic cube 13 and the first dichroic cube 12 have a wavelength selectivity at UV lights from UV-LEDs 21A, 21B and 21C. Three UV lights having different peak-wavelengths from one another are split, and each one of split light (the aforementioned image-writing light) is introduced into the respective read light valves 31, 32 and 33. Specifically, first image-writing light based on the blue color video signal is directed to the read light valve 31, second image-writing light based on the green color video signal is directed to the read light valve 32, and third image-writing light based on the red color video signal is directed to the read light valve 33.

As disclosed in the pamphlet of International Laid-Open WO 2005/116719, the read light valves 31, 32 and 33 are composed of an OASLM (Optically Addressed Spatial Light Modulator) having a photoconductive effect. For example, with a configuration in which liquid crystal layer is interposed between optically transparent electrode structures having a photoconductive effect, a change of photoconductive effect occurs in only a portion where light is irradiated, with the result that a change of a voltage applying to the liquid crystal occurs in said portion where light is irradiated, changing a state of rotation of the liquid crystal. In each of the read light valves 31, 32 and 33, the so-called pixel-electrode is unnecessary. It can be described that pixel of the read light valves appear when optical writing was performed.

(Configuration for Reducing Distortion)

Next, a configuration which enables to reduce inconvenience (distortion of the projected image, chromatic aberration of magnification of the projected image) due to an optical cause, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, will be described. FIG. 3A shows a situation where a quadrangle shape image written into the write light valve is written into the read light valves 31, 32 and 33, through the imaging lens group 26 and the written images by using light on these read light valves are projected on a screen. It should be noted that, for comparison purposes, FIG. 3B shows the same situation in the conventional projection type video display 100.

In the conventional projection type video display 100, as shown in FIG. 3B, the quadrangle shape image written into the write light valve (125) is written into the read light valve through the imaging lens group(126) without being distorted. However, the written image by using light on the read light valve is distorted when it is projected due to distortion aberration of the projection lens (114) and has pincushion distortion on the screen. On the other hand, in the projection type video display according to the present invention, the quadrangle shape image written into the write light valve 25 is written into the read light valve with being distorted like a barrel shape due to the imaging lens group 26. And then the written image by using light on the read light valve is distorted when it is projected due to distortion aberration of the projection lens 14 and changes to quadrangle shape on the screen.

Usually, a distortionless lens is used as the relay lens group, but the projection type video display 50 according to the embodiment, the distortionless lens is not used as the imaging lens group 26. That is, the distortion aberration is given in the imaging lens group 26 intentionally. The distortion aberration of the imaging lens group 26 is in reverse relation to the distortion aberration of the projection lens 14. Specifically, the projection lens 14 distorts an image so that the quadrangle shape image changes to a pincushion shape, while the imaging lens group 26 distorts an image so that the quadrangle shape image changes to a barrel shape. That is, the imaging lens group 26 is optically designed so that the quadrangle shape image is deformed into the barrel shape. The degree of distortion of the imaging lens group 26 is set depending on the degree of distortion aberration of the projection lens. It should be noted that the barrel distortion may occur in the projected image projected through the projection lens 14, and the pincushion distortion may occur in the image-writing light in the imaging lens group 26.

Hear, an image processing circuit in the driver distorts the image so that the image changes to the barrel shape image, when the image is written into the write light valve (see FIG. 14A). While, with the above-described embodiment, the image processing circuit is unnecessary

FIG. 4A shows a situation where the written image by using light on the read light valves 31, 32 and 33 is projected on the screen. It should be noted that, for comparison purposes, FIG. 4B shows the same situation in the conventional projection type video display 100. It assumes that the projection lens 14 (114) has a high chromatic aberration of magnification. In this case, as shown FIG. 4 B, in a case where the sizes of the written images by using light on the read light valves are the same, color projected images on the screen are different from one another in size. Specifically, in a case where a center of blue color wavelength is denoted by λ11, a center of green color wavelength is denoted by λ12 and a center of red color wavelength is denoted by λ13, a relationship of λ11<λ12<λ13 is satisfied. Therefore, a red color image is the largest image, a blue color image is the smallest image, and a green color image is a middle size of these due to a chromatic aberration of magnification.

In the projection type video display 50 according to the present invention, it is defined properly that which color image the display writes by selecting which of these UV-LEDs. That is, when a wavelength of light of image is longer, the display 50 selects write light (UV) with shorter wavelength in the image-writing. As described above, the peak wavelengths of the UV-LEDs 21A, 21B and 21C are different from one another (λ1>λ2>λ3). Further, in the color illumination light, a relationship of λ11<λ12<λ13 is satisfied. Under the aforementioned condition, the image-writing to the read light valve 31 on which the color illumination light with wavelength λ11 (blue color) is incident is performed with the write light of the LED 21A, the image-writing to the read light valve 32 on which the color illumination light with wavelength λ12 (green color) is incident is performed with the write light of the LED 21B, the image-writing to the read light valve 33 on which the color illumination light with wavelength λ13 (red color) is incident is performed with the write light of the LED 21C. Accordingly, as shown in FIG. 3A, an order of size of the written image by using light is described in order of a blue image, a green image, a red image, thus reducing effect of a chromatic aberration of magnification of projection lens 14. In other words, with the aforementioned configuration, when an optics design of compensation of a chromatic aberration of magnification in the projection lens 14 is done, a degree of correction of a chromatic aberration of magnification is reduced, thus improving the degree of freedom in a design of the projection lens 14. It should be noted that, depending on a combination of a lens in the projection lens 14(114), there is such a case a blue color image is the largest, a red color image is the smallest, a green color image is a middle size of these. In this case, when a wavelength of light of image is longer, the display 50 selects write light (UV) with longer wavelength in the image-writing.

It should be noted that the optical system shown in FIG. 2 is an example, and a configuration in which three UV lights whose wavelengths are different from one another are emitted by switching irradiation by using of a single UV-LED can be adopted (see FIG. 15 in the pamphlet of International Laid-Open WO 2005/116719). Further, a configuration comprising a dichroic X cube which combines three image lights together and a dichroic cube(for introducing the writ light) which is placed between the dichroic X cube and the projection lens is known (see FIG. 16 in the pamphlet of WO2005/116719). It this configuration, it can be considered that above-described distortion-reduction configuration is especially effective. That is, in a configuration in which two cubes are disposed adjoining each other at the light incidence side of the projection lens for combining of each color image and for introducing of write lights, for example (also see FIGS. 17A and 17B in the pamphlet of International Laid-Open WO 2005/116719), it can be considered that above-described distortion-reduction configuration is especially effective.

It should be noted that the optical system shown in FIG. 2 is an example, the present invention is not limited to providing the UV LED with respect to the aforementioned configuration which reduces a chromatic aberration of magnification described above. It is possible to obtain three UV lights with three different wavelengths one another from a light source 1 (see FIG. 14B in the pamphlet of International Laid-Open WO 2005/116719).

FIG. 5 shows an another example of a projection type video display of the present invention. The projection type video display 50 is provided with an image formation optical system 40 at the light exit side of the second dichroic cube 13. A reduced image formation plane (first image formation plane) of an image that is displayed on the read light valve is formed through the image formation optical system 40. The reduced image formation plane functions as an object plane of the projection lens 14A, and is projected through the projection lens 14A. With the above-mentioned configuration, the distance between the aforementioned image formation plane and a rear-element lens of the projection lens 14A can be set optionally, thereby making it possible to use a small-aperture projection lens having short back focal length whose price is low.

FIG. 6 shows an another example of a projection type video display which has the image formation optical system 40. Image lights which are formed by image display panels 41, 42 and 43 are combined together through a cross dichroic cube 44. The image display panels 41, 42 and 43 are not limited to the read light valve (the OASLM having a photoconductive effect), but may be a general liquid crystal display panel having a pixel electrode. Furthermore, it is possible to employ a configuration having the reflection-type image display panel such as LCOS or DMD (Digital Micromirror Device) as the image display panels 41, 42 and 43.

FIG. 7 shows an another example of a projection type video display which has the image formation optical system 40. Each of image lights which is formed by transmission-type image display panels 41, 42 and 43 passes through the image formation optical systems 40. The reduced image formation planes (first image formation planes) of images that are displayed on the read light valves are formed through the image formation optical systems 40. The reduced image formation planes are combined together through a cross dichroic cube 45, and are projected through the projection lens 14A. With the configuration shown in FIG. 7, the image formation planes are provided at the light incident side of the cross dichroic cube 45, thereby making it possible to downsize the cross dichroic cube 45.

With the projection type video display in this embodiment, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, an inconvenience (distortion of the projected image, chromatic aberration of magnification of the projected image) due to an optical cause can be reduced.

(Mechanism for Downsizing)

Next, a configuration using a single transmission-type read light valve, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, is desired. That is, with this configuration, downsizing and cost cutting of the projection type video display are realized. Hereinafter, a projection type video display which can realize downsizing, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, will be described.

FIG. 8 is an explanation view illustrating an embodiment of a single-panel type projection type video display 51A. Out of the components in FIG. 2, the components common with that in the projection type video display are referred to by the same numerals and descriptions thereof will be omitted. The projection type video display 51A is provided with a red color LED 1R, a green color LED 1G and a blue color LED 1B, as a light source. These LEDs 1R, 1G and 1B are turned on in a time-sequential manner. Color light emitted from each LED is incident on a tapered rod integrator 27. Each color light passes through the rod integrator 27 to provide a surface illuminant with uniform light intensity and with low divergence angle at the exit surface of the rod integrator 27. Each color light emitted from the exit surface is introduced into a dichroic cube 28 after passing through a read light valve 34. The dichroic cube 28 reflects UV light while transmitting visible light.

The read light valves 34, as disclosed in the pamphlet of International Laid-Open WO 2005/116719, is composed of an OASLM (Optically Addressed Spatial Light Modulator) having a photoconductive effect. For example, with a configuration in which liquid crystal layer is interposed between optically transparent electrode structures having a photoconductive effect, a change of photoconductive effect occurs in only a portion where light is irradiated, with the result that a change of a voltage applying to the liquid crystal occurs in said portion where light is irradiated, changing a state of rotation of the liquid crystal.

Next, image writing optical system will be described hereinbelow. The image writing optical system includes a single UV-LED (light-emitting diode) 21. The UV light emitted from the UV-LED 21 is incident on the rod integrator 22. The UV light passes through the rod integrator 22 to provide a surface illuminant with uniform light intensity at the exit surface of the rod integrator 22. The UV light emitted from the exit surface is introduced into the polarization beam splitter 24 after passing through the relay lens group 23.

First particular polarized light (for example, P-polarized light) which has passed through the polarization beam splitter 24 is directed to the write light valve (LCOS device) 25 which modulates write lights (said UV lights). The write light valve 25 generates images for respective colors in a time-sequential manner with the driver 70. That is, the driver 70 writes a first image into the write light valve 25 based on the blue color video signal, writes a second image into the write light valve 25 based on the green color video signal, and writes a third image into the write light valve 25 based on the red color video signal. The forming of the first image, the forming of the second image, and the forming of the third image are sequentially repeated.

The write light valve 25 generates image light by modulating a received first particular polarized light. The aforementioned image light is obtained as reflected light, and the reflected light is changed into the second particular polarized light (for example, S-polarized light). That is, when the first particular polarized light is provided on the write light valve 25, image-writing light having the second particular polarized light (S-polarized light) is generated. The image-writing light emitted from the write light valve 25 is reflected on the polarization beam splitter 24. The image-writing light is introduced into the dichroic cube 28 through the imaging lens group (image formation optical system) 26.

As described above, the dichroic cube 28 reflects UV light while transmitting visible light. The image-writing light which is UV light is introduced into the read light valve 34 after reflecting on the dichroic cube 28 to write the image on the read light valve 34. At the time that the first image is written, the blue color LED 1B turns on, which irradiates the blue light to the read light valve 34. At the time that the second image is written, the green color LED 1G turns on, which irradiates the green light to the read light valve 34. At the time that the third image is written, the red color LED 1R turns on, which irradiates the red light to the read light valve 34.

Each color image light which is obtained by each color light passing through the read light valve 34 is introduced into the projection lens 14 after passing through the dichroic cube 28. Each color image light is projected onto a not-shown screen through the projection lens 14.

It should be noted that an polarization beam splitter (28A) may be used in place of the dichroic cube 28. In this case, a read light valve 34A not having a light exit-side polarizer is used (see FIG. 9).

Next, with reference to FIG. 9, an embodiment of a single-panel type projection type video display of the present invention will be described. FIG. 9 shows an optical system of a projection type video display 51 of this embodiment. The components common with that in the projection type video display 51A are referred to by the same numerals and descriptions thereof will be omitted.

The projection type video display 51 has a polarization beam splitter 28A in place of the dichroic cube 28. In FIG. 9, at the right side of the polarization beam splitter 28A, there are provided a UV-LED 21, a tapered rod integrator 29, a polarizer (a dielectric multi-layered film, a wire grid or the like) 35 and the like, while at the left side of the polarization beam splitter 28A, there are provided the imaging lens group (image formation optical system) 26 and the write light valve 25. UV light emitted from the UV-LED 21 is incident on the rod integrator 29. The UV light passes through a rod integrator 29 to provide a surface illuminant with uniform light intensity and with low divergence angle at the exit surface of the rod integrator 29.

Out of the emitted UV light from the light exit surface, only the P-polarized light passes through the polarizer 35, for example, and then the P-polarized light is introduced into the write light valve 25 after passing through the polarization beam splitter 28A and passing through the imaging lens group 26. The image-writing light (S-polarized light) which is obtained by UV light (write light) being reflected on the write light valve 25 is imaged on the read light valve 34A after passing through the imaging lens group 26 and being reflected on the polarization beam splitter 28A. An image for each color which is formed on the read light valve 34A is read out by each color illumination light, and is introduced into the projection lens 14 after passing through the polarization beam splitter 28A. The read light valve 34A has not the light exit-side polarizer, while the polarization beam splitter 28A functions as the light exit-side polarizer.

With the aforementioned projection type video display 51, it is possible to eliminate the polarization beam splitter 24 which is needed for the projection type video display 51A.

Further, with reference to FIG. 10, an embodiment of a single-panel type projection type video display of the present invention will be described. FIG. 10 shows an optical system of a projection type video display 52 of this embodiment. The components common with that in the projection type video display 51 are referred to by the same numerals and descriptions thereof will be omitted.

The projection type video display 52 has the polarization beam splitter 28A same as the projection type video display 51 in place of the dichroic cube 28. In FIG. 10, at the right side of the polarization beam splitter 28A, there are provided the UV-LED 21, the rod integrator 22, the relay lens group 23, and the polarizer 35, while at the left side of the polarization beam splitter 28A, there is provided the write light valve 25. Further, the imaging lens group 26 (image formation optical system) is placed between the read light valve 34A and the polarization beam splitter 28A.

The UV light emitted from the UV-LED 21 is incident on the rod integrator 22. The UV light emitted from the rod integrator 22 is introduced into the polarizer 35 after passing through the relay lens group 23. Only the P-polarized light which was able to pass through the polarizer 35, for example, is introduced into the write light valve 25 after passing through the polarization beam splitter 28A. The image-writing light (S-polarized light) which is obtained by UV light (write light) being reflected on the write light valve 25 is imaged on the read light valve 34A after being reflected on the polarization beam splitter 28A and passing through the imaging lens group 26. An image for each color which is formed on the read light valve 34A is read out by each color illumination light, and then passes through the polarization beam splitter 28A after passing through the imaging lens group 26. When the image light for each color emitted from the read light valve 34A passes through the imaging lens group 26, an image formation surface of the image for each color is formed between the polarization beam splitter 28A and the projection lens 14.

With the aforementioned projection type video display 52, the image formation plane is formed near the rear-element lens of the projection lens 14, thereby making it possible to use a small-aperture projection lens having short back focal length.

It should be noted that it is possible to use a light source shown in FIG. 11 as the light source of the projection type video display 50, 51A, 51 and 52. The light source is provided with the red color LED 1R, the green color LED 1G and the blue color LED 1B, at a light incidence surface of a cross dichroic cube 36 respectively. From a light exit surface of the cross dichroic cube 36, each color light emitted from each LED is emitted. Each color light is incident on a tapered rod integrator 27A. A polarization conversion device 37 is placed at a light exit surface of the tapered rod integrator 27A. The polarization conversion device 37 has a dielectric multi-layered film (polarized light separating surface) in V-shaped at a position facing the light exit surface of the rod integrator 27A. S-polarized light reflected on one surface of the dielectric multi-layered film is reflected by an adjacent reflecting member thereof (or a dielectric multi-layered film); similarly, S-polarized light reflected on the other surface of the dielectric multi-layered film is reflected by an adjacent reflecting member thereof (or a dielectric multi-layered film). P-polarized light which has passed through the dielectric multi-layered film is converted to S-polarized light by the retardation plate (½λ plate). That is, the light is aligned to the S-polarized light. As a matter of course, light can be aligned to P-polarized light.

With these aforementioned single-panel type projection type video displays, a projection type video display using a single read light valve is realized.

Further, in these aforementioned single-panel type projection type video displays, its imaging lens group 26 may have a distortion aberration which reduces or cancels out a distortion aberration of the projection lens 14 (see FIG. 3A). Furthermore, in the configuration such as FIG. 8, 9, or 10, there may be provided three UV-LEDs 21A, 21B and 21C with three different wavelengths one another (see FIG. 2) or a single UV-LED which emits three UV-light with three different wavelengths one another in a time-sequential manner. With these configurations, it is possible to write an image by the write light with shorter wavelength when a wavelength of light of image is longer, for example. Thereby, it is possible to reduce the difference of size of projected images due to the chromatic aberration of magnification.

It should be noted that the single-panel type projection type video displays is not limited to the configuration shown in FIG. 8, 9, or 10. With a configuration which has the light optical system, a distortion of the projected image can be reduced. Further, with a construction which emits write lights having different wavelengths one another, the chromatic aberration of magnification can be reduced. Further, in the three-panel type projection type video display, also, it is possible to employ solid light-emitting elements such as a white color LED or respective color LEDs in place of the light source 1.

(Configuration for Reducing Convergence Error)

Next, a configuration which enables to reduce inconvenience (convergence error, distortion of the projected image, chromatic aberration of magnification of the projected image) due to an optical cause, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, will be described. FIG. 12A shows a situation where a quadrangle shape image written into the write light valve is written into the read light valves 31, 32 and 33, and each written image by using light on these read light valves are projected on a screen. It should be noted that, for comparison purposes, FIG. 12B shows the same situation in the conventional projection type video display 100.

[Convergence]

In the conventional projection type video display 100, as shown in FIG. 12B, images for optical writing (the quadrangle shape image) are written into the same position on the write light valve(125). In a case where an accuracy of the position, the direction and so on of each element of the write optical system (including a portion overlapping with a read optical system), however, a relative shift of the position of the written image by using light occurs. Therefore, there is the fear that a convergence is not obtained.

With the projection type video display 50 of the present invention, the driver 70 adjusts the position of the image for each color which is written into the write light valve based on the given position adjustment amount. For example, in a test before leaving the factory, a convergence adjustment is executed by means of projection of a test pattern. For example, with the purpose of defining the shift amount of the image for each color, an up-and-down adjustment volume and a right-and-left adjustment volume are provided for each color. The tester adjusts the volumes in the convergence adjustment process. The adjusted resistance values (voltage value) of the volumes are supplied to the driver 70. The driver 70 shifts the image writing position on the write light valve 25 to rightward, leftward, upward, or downward only by one pixel or by some pixels with respect to each color based on the adjusted resistance value (that is, a given position adjustment amount). In a state where the convergence adjustment is perfected, the volumes may be locked. Or, it may be configured such that a key indicating a completion of convergence is provided and said position adjustment amount is stored in a memory in digital value when the key is operated, and the driver 70 obtains said position adjustment amount from the memory in the image processing.

As described above, since the convergence adjustment can be executed by means of control of image-writing for each color to the write light valve 25, the adjustments for position and attitude of a constructional element constituting the optical system which writes the image into each of the read light valves are not particularly necessary. Further, the convergence adjustment is executed with writing control to the single write light valve 25.

[Chromatic Aberration of Magnification]

FIG. 13A shows a situation where a written image using light on the read light valves 31, 32 and 33 are projected on the screen. It should be noted that, for comparison purposes, FIG. 13B shows the same situation in the conventional projection type video display 100. Here, it is assumed that the projection lens 14 (114) has a large chromatic aberration of magnification. In this case, as shown in FIG. 13B, in a case where the size of images for optical writing on the write light valve are the same, the size of each written image using light on the read light valves become the same one another, which causes difference of the size of each color projected image on the screen. Specifically, when a center of blue color wavelength is denoted by λ11, a center of green color wavelength is denoted by λ12, and, a center of red color wavelength is denoted by λ13, a relationship of λ11<λ12<13λ is satisfied. Therefore a red color image is the largest, a blue color image is the smallest, a green color image is a middle size of these due to a chromatic aberration of magnification. It should be noted that depending on a combination of lenses in the projection lens 14(114), there is such a case a blue color image is the largest, a red color image is the smallest, a green color image is the a middle size of these.

With the projection type video display 50 of the present invention, the driver 70 adjusts the size of the image for each color which is written into the write light valve based on the given size adjustment amount. For example, it can be considered that one size adjusting volume is provided for each color, with the purpose of defining the size of the image with respect to each color. Since we can knew the chromatic aberration of magnification of the projection lens 14 previously, however, it is able to provide a data indicating the size of the image with respect to each color previously to the driver 70. The driver 70 adjusts the size of the image into the write light valve 25 based on the data indicating the size of the image for each color (that is, a given size adjustment amount).

For example, if the write light valve 25 is designed for 1024×768 dots. Further, (1) the driver generates image data by data sampling or pixel skipping according to 1024×768 dots, and writes the image data with using 1024×768dots in the write light valve 25 with respect to inputted blue color video signal, for example, (2) the driver generates image data by data sampling or pixel skipping according to 1022×766 dots, and writes the image data with using 1022×766 dots in the write light valve 25 with respect to inputted green color video signal, for example, and (3) the driver generates image data by data sampling or pixel skipping according to 1020×764 dots, and writes the image data with using 1020×764 dots in the write light valve 25 with respect to inputted red color video signal, for example.

It should be noted that it is fixed that the size of the image for each color is made to differ as described above, and an optical design of the projection lens 14 may be executed with respect to a chromatic aberration of magnification. In this case, the degree of correction of a chromatic aberration of magnification is reduced, thus improving the degree of freedom in design of the projection lens 14.

[Reduction of Distortion]

FIG. 14A shows a situation where a quadrangle shape image inputted as image data is distorted intentionally in barrel shape with image processing and the distorted image is written into the write light valve 25, and the barrel shape image is similarly written into the read light valves 31, 32 and 33 through the imaging lens group 26, and the written image (the barrel shape) returns to a quadrangle shape image by distortion aberration of the projection lens when the image (the barrel shape image) is projected. It should be noted that, for comparison purposes, FIG. 14B shows the same situation in the conventional projection type video display 100.

In the conventional projection type video display 100, as shown in FIG. 14B, the quadrangle shape image written into the write light valve(125) is similarly written into the read light valve through the imaging lens group(126). However, the written image by using light on the read light valve is distorted due to distortion aberration of the projection lens (114) and has a pincushion shape on the screen. On the other hand, in the projection type video display 50 according to the present invention, since the barrel shape image is written into the write light valve 25, the barrel shape image is also written into the read light valve by using light. And then, the barrel shape image is projected through the projection lens 14, thereby forming the quadrangle shape image on the screen.

That is, with the projection type video display 50 of the present invention, the driver 70 generates image data that is a distorted image based on the given distortion adjustment amount and writes the distorted image into the write light valve based on the image data. For example, it can be considered that one volume is provided, with the purpose of defining the degree of the distortion of the image. Sine we can know the distortion aberration of the projection lens 14 previously, however, it is able to provide the data defining the degree of the distortion previously to the driver 70. The driver 70 processes the image so that the quadrangle shape image is deformed into a barrel shape based on the data defining the degree of the distortion (that is, a given distortion adjustment amount). A method of texture mapping which maps a 2-D image onto a 3-D surface is utilized as an example of the aforementioned processing.

It should be noted that in a case where the barrel shape distortion occurs in the image projected through the aforementioned projection lens 14, an image processing which is the reverse of the aforementioned image processing may be employed. That is, the driver 70 may carry out the image processing for transforming the image to the pincushion shape based on an inputted image data.

Further, the optical system shown in FIG. 2 is an example, the present invention is not limited to providing three UV-LEDs whose wavelengths are different from one another. For example, a configuration in which three UV lights whose wavelengths are different from one another are emitted by switching irradiation by using of a single UV-LED can be adopted (see FIG. 15 in the pamphlet of International Laid-Open WO 2005/116719). Further, a configuration comprising a dichroic X cube which combines three image lights together and a dichroic cube (for introducing the write light) which is placed between the dichroic X cube and the projection lens is known (see FIG. 16 in the pamphlet of WO2005/116719). It this configuration, it can be considered that the configuration of the present invention is especially effective. The reason is that it is thought that the aforementioned distortion aberration is likely to occur in a configuration in which two cubes are disposed adjoining each other at the light incidence side of the projection lens for combining of each color image and for introducing of write lights, for example (also see FIGS. 17A and 17B in the pamphlet of International Laid-Open WO 2005/116719.)

In the single-panel type projection type video display as shown in FIGS. 8, 9 or 10, as described above, the driver 70 adjusts the size of the image for each color which is written into the write light valve based on the data indicating the size of the image for each color (that is, a given size adjustment amount). Accordingly, it is possible to reduce inconvenience due to a chromatic aberration of magnification of the projection lens 14. Further, the aforementioned driver 70 carries out an image processing so that the quadrangle shape image is deformed into a barrel shape based on the data defining the degree of the distortion (that is, a given distortion adjustment amount). Accordingly, it is possible to resolve or reduce inconvenience due to the aforementioned distortion aberration of the projection lens 14. It should be noted that the single-panel type projection type video display is not limited to the configuration shown in FIGS. 8, 9 or 10. Further, in the three-panel type projection type video display, also, it is possible to employ a solid light-emitting elements such as a white color LED, each color LED or the like in place of the light source 1.

With the projection type video display in this embodiment, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, an inconvenience (convergence error, distortion of the projected image and chromatic aberration of magnification of the projected image) due to an optical cause can be reduced.

(Configuration not Having Lens Shift Device)

Conventionally, there have been known lens shift devices for shifting a position of projection image without moving the body of the display. FIG. 15 shows a lens shift device 200 with a bearing as an example of the lens shift devices (see Japanese Patent No.3643817). In the lens shift device for shifting the projection lens, however, high hardness and a high-power motor are needed, thereby increasing in size, weight or cost, in the projection type video display. A configuration in which a mechanism which shifts the projection image without moving the body of the display, without increasing in size, weight and cost of the display, is provided, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, will be described hereinafter. In view of the shifting of the write light valve 25, each of the read light valves 31, 32 and 33 has a rather large size so as to receive the image-writing light in the range of the shift. In the read light valves 31, 32 and 33, since the so-called pixel-electrode is unnecessary as described above, there is almost no increase in cost, even if it is large.

FIG. 16 is an explanation view showing an optical path changing, in a simplified optical system, in a case where the write light valve 25 is shifted. When the write light valve 25 is shifted, which shifts the position of the image-writing light in the common direction on the all the read light valves 31, 32 and 33 accordance with the shift amount. When the image-writing light is shifted, which shifts the projection image on the screen. In view of the shifting of the write light valve 25, a flexible wiring is utilized as a wiring which supplies a driving signal.

FIG. 17 is an explanation view showing an optical path changing, in a simplified optical system, in a case where the imaging lens group 26 is shifted. When the imaging lens group 26 is shifted, which shifts the position of the image-writing light in the common direction on the all the read light valves 31, 32 and 33 accordance with the shift amount. When the image-writing light is shifted, which shifts the projection image on the screen.

In a case where the configuration in FIG. 16 is employed, the size of the write light valve 25 is sufficiently smaller than the irradiation area of write light (i.e., the surface of the polarization beam splitter 24). Even when the write light valve 25 is shifted, the write light valve 25 can receive write light at any position to which the write light valve 25 is moved.

It is possible to use the lens shift device shown in Japanese Unexamined Patent Publication No. 2004-245956, for example, as a light valve shift device which shifts the writ light valve 25. Specifically, as shown in FIGS. 19A and 19B, the light valve shift device is equipped with a first fixed-side plate 311, a second fixed-side plate 312, a light valve holder 313, and drive mechanism sections 314A and 314B. The second fixed-side plate 312 is fixed in a manner that its external surface used as a datum plane is contacted with the chassis of the projection type video display. The write light valve 25 is fixed to the light valve holder 313. The light valve holder 313 is pinched by the first fixed-side plate 311 and the second fixed-side plate 312 and can move in the directions of up-and-down and right-and-left by being guided with the plate 311 and 312. Both surfaces of the light valve holder 313 and each inner surface of the fixed side plate 311 and 312 which meets the aforementioned surfaces of the light valve holder 313 function as a sliding surface.

A quadrangle opening having the size which is corresponding to a permissible moving range of the write light valve 25 is formed in the first fixed-side plate 311 and the second fixed-side plate 312 respectively. Furthermore, openings which permit moving of a pair of pinions 441 and 411 of the drive mechanism section 314A and 314B are formed in the second fixed-side plate 312, and a pair of racks 313 a and 313 a which bite said pinions 441 and 411 are formed in the light valve holder 313. Widths of the racks 313 a and 313 a are set in consideration of the permissible moving range of the write light valve 25 and the tooth widths of the racks. The above-mentioned pinions 441 and 441 are fixed to the revolving shaft 445. The revolving shaft 445 is supported rotateably by bearing 312 c placed in the front face of the second fixed-side plate 312.

A supporting portion 312 a is formed in the edge of the second fixed side plate 312. A supporting hole 312 b is formed in parallel with the surface of the second fixed-side plate 312, and the adjustment dials 442 and 442 of the drive mechanism sections 314A and 314B are inserted in the supporting holes 312 b and 312 b. The adjustment dial 442 comprises a worm gear 442 a and a knob 442 b placed in the head side of the worm gear 442 a. An E-ring 443 is engaging with the middle section of worm gear 442 a, preventing the adjustment dial 442 from falling. Further the worm wheel 444 is screwed in the gear field of worm gear 442 a. The worm wheel 444 is fixed to the center of the aforementioned revolving shaft 445.

When the worm gear 442 a is rotated by turning the adjustment dial 442 of the drive mechanism section 314A, the worm wheel 444 is rotated. When worm wheel 444 rotates, a revolving shaft 445 is rotated to rotate respectively the pinions 441 and 441. And then turning efforts of above-mentioned pinions 441 and 441 are transmitted respectively to racks 313 a and 313 a, which move the light valve holder 313 in the direction of line C-D. Since a convex portion and a concave portion of the racks 313 a and 313 a of the side of the drive mechanism section 314B are formed in the direction of line C-D, a guide function is offered while permitting the C-D direction movement of the light valve holder 313.

Similarly, when the worm gear 442 a is rotated by turning the adjustment dial 442 of the drive mechanism section 314B, the worm wheel 444 is rotated. When worm wheel 444 rotates, the revolving shaft 445 is rotated to rotate the pinion 441 and 441. And then turning efforts of the pinions 441 and 441 are transmitted respectively to the racks 313 a and 313 a, which move the light valve holder 313 in the direction of line E-F. Since a convex portion and a concave portion of the racks 313 a and 313 a of the side of the drive mechanism section 314A are formed in the direction of line E-F, a guide function is offered while permitting the E-F direction movement of the light valve holder 313.

Although the aforementioned light valve shift device has a configuration in which the front surface, which functions as the datum plane, of the second fixed-side plate 312 is fixed in a chassis of the projection type video display in the example explained above, the light valve shift device is not limited to these embodiments. A configuration in which a rear surface, which functions as a datum plane, of the first fixed-side plate 311 is met to a surface of the polarization beam splitter 24 may be used. This makes it possible to keep adequately the positional relationship between of the polarization beam splitter 24 and the write light valve 25. In addition, although the light valve shift device capable of manual shifting by using the adjustment dial 442 in the example explained above, the light valve shift device is not limited to these embodiments. An electric actuator such as by utilizing a motor may rotate the worm gear 442 a. The electric actuator is turned on or off with a switching operation of an operation panel.

A configuration same as the configuration shown in FIG. 19 may be adopted as a mechanism which shifts the imaging lens group 26. In this case, it is not easy to operate by manual using the adjustment dial 442. Therefore, it is desirable that the electric actuator such as by utilizing a motor rotates the worm gear 442 a.

Although in the above-mentioned example, the write light valve 25 is made to shift, present invention is not limited to this. It may be configured such that a write light valve 25A is provided, as shown in FIG. 20, and an image which is written into the write light valve 25A is shifted. The size of the write light valve 25A is larger than the size of the write light valve 25. For example, if the write light valve 25 designed for 1024×768 dots, the write light valve 25A is designed for 2048×1536 dots. A shift-indication-operation unit in which a shift-indication signal is inputted by an user operation is mounted in the projection type video display. The shift-indication-operation unit comprises an up-and-down adjustment volume, a right-and-left adjustment volume, and a processor which generates an adjustment value of up-and-down and right-and-left based on a value of resistance (a value of voltage) obtained from said volumes, they are mounted in the projection type video display. Or, the shift-indication-operation unit comprises a direction indication key placed on a remote controller, and a processor which increases or decrease an adjustment value of up-and-down and right-and-left based on a signal obtained when said key is operated.

The driver 70 adjusts the position of the image which is written into the write light valve based on said adjustment values of up-and-down and right-and-left. For example, if the adjustment values of up-and-down and right-and-left are 384 and 512, the driver 70 writes the image into the center in a direction of up-and-down and right-and-left of the write light valve 25A. And then, if the adjustment values of up-and-down and right-and-left change to 385 and 512, the driver 70 shifts the image writing position upward by only one pixel, while if the adjustment values of up-and-down and right-and-left change to 383 and 512, the driver 70 shifts the image writing position downward by only one pixel. In addition, if the adjustment values of up-and-down and right-and-left change to 384 and 513, the driver 70 shifts the image writing position rightward by only one pixel, while if the adjustment values of up-and-down and right-and-left change to 384 and 511, the driver 70 shifts the image writing position leftward by only one pixel.

It should be noted that the optical system shown in FIG. 2 is an example, and a configuration in which three UV lights whose wavelengths are different from one another are emitted by switching irradiation by using of a single UV-LED can be adopted (see FIGS. 16A, 17A and 17B in the pamphlet of International Laid-Open WO 2005/116719). Further, if the three optical paths of write lights for each color are optically equivalent with one another, in a case where the one write light valve 25A is moved, which shifts three image-writing lights using light in a same direction. On the other hand, if the three optical paths of write lights for each color are not optically equivalent with one another (in a case where an image reversing occurs due to a presence of a relay lens optical system in only one optical path, for example) (see FIG. 15 in the pamphlet of International Laid-Open WO 2005/116719), a configuration having the light valve shift device is not adopted. On the other hand, the aforementioned configuration in which the image writing position on the write light valve is shifted is adopted, even if in a case where the image reversing occurs, because the aforementioned configuration is able to reverse the shift direction of the written image for blue light, e.g., with respect to the shift direction of the written image for the other color light.

It is possible to adopt the shift mechanism which shifts the write light valve 25 or the shift mechanism which shifts the imaging lens group (image formation optical system) 26 in the single-panel type projection type video display as shown in FIG. 8, 9 or 10. In addition, it is possible to shift the writing position of the image by adopting the write light valve 25A in the projection type video display. It should be noted that the single-panel type projection type video displays is not limited to the configuration shown in FIGS. 8, 9 or 10. Further, in the three-panel type projection type video display, also, it is possible to employ a solid light-emitting elements such as a white color LED, each color LED or the like in place of the light source 1

With the projection type video display in these embodiments, in a projection type video display in which an image writing to a read light valve which generates projection image light is performed by using light, effects such that a mechanism which shifts the projection image without moving the body of the display is simplified in comparison whit the convention are obtained.

OTHER EMBODIMENTS

Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims. 

1. A projection type video display, comprising: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; read light valves for each color, in which an image is written by the image-writing light emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the respective read light valves; means for combining together color image lights emitted from the respective read light valves; and a projection optical system for projecting each color image light combined together, wherein the writing optical system has a distortion aberration which reduces or cancels out a distortion aberration of the projection optical system.
 2. The projection type video display according to claim 1, wherein a pincushion distortion occurs in the projection image projected through the projection optical system, and a barrel distortion occurs in the image-writing light in the writing optical system.
 3. The projection type video display according to claim 1, wherein a barrel distortion occurs in the projection image projected through the projection optical system, and a pincushion distortion occurs in the image-writing light in the writing optical system.
 4. A projection type video display, comprising: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; read light valves for each color, in which an image is written by the image-writing light emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the respective read light valves; means for combining together color image lights emitted from the respective read light valves; and a projection optical system for projecting each color image light combined together, wherein sizes of written images on the respective read light valves are different from one another due to the write lights having different peak-wavelengths, with the result that a difference in size of each color projected image on a screen is reduced due to the occurrence of a chromatic aberration of magnification in the projection optical system.
 5. The projection type video display according to claim 4, wherein on the condition that a peak-wavelength of each write light is denoted by λ1, λ2, λ3 (λ1>λ2>λ3) and a wavelength of each color illumination light is denoted by λ11, λ12, λ13 (λ1<λ12<λ13), an image writing using the write light with wavelength λ1 is performed when the color illumination light with wavelength λ11 is incident on the read light valve, an image writing using the write light with wavelength λ2 is performed when the color illumination light with wavelength λ12 is incident on the read light valve, and an image writing using the write light with wavelength λ3 is performed when the color illumination light with wavelength λ13 is incident on the read light valve.
 6. The projection type video display according to claim 1 or 4, wherein the driver adjusts a position of the image for each color which is written into the write light valve based on a given position adjustment amount.
 7. The projection type video display according to claim 1 or 4, wherein the driver adjusts the size of the image for each color which is written into the write light valve based on a given size adjustment amount.
 8. The projection type video display according to claim 1 or 4, wherein there is provided a shift device for shifting the write light valve or the writing optical system up-and-down and/or right-and-left in a plane perpendicular to an optical axis of the image writing.
 9. The projection type video display according to claim 1 or 4, wherein there is further provided a shift instruction operation portion which inputs a signal indicating a shift by an user operation, wherein the driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift.
 10. A projection type video display, comprising: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; a single read light valve, in which images are written by the image-writing lights emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the read light valve; and a projection optical system for projecting the image light emitted from the read light valve, wherein the writing optical system has a distortion aberration which reduces or cancels out a distortion aberration of the projection optical system.
 11. A projection type video display, comprising: a write light valve for generating image-writing light by modulating write light; a driver for writing images into the write light valve based on image data; a single read light valve, in which images are written by the image-writing lights emitted from the write light valve, for generating respective color image lights by modulating each received color illumination light; a writing optical system for guiding the image-writing light emitted from the write light valve to the read light valve; and a projection optical system for projecting the image light emitted from the read light valve, wherein the sizes of written images on the read light valve are different from one another due to the write light having different peak-wavelengths, with the result that a difference in size of each color projected image on a screen is reduced due to the occurrence of the chromatic aberration of magnification in the projection optical system.
 12. The projection type video display according to claim 11, wherein on the condition that a peak-wavelength of each write light is denoted by λ1, λ2, λ3 (λ1>λ2>λ3) and a wavelength of each color illumination light is denoted by λ11, λ12, λ13 (λ11<λ2<λ13), an image writing using the write light with wavelength λ1 is performed when the color illumination light with wavelength λ11 is incident on the read light valve, an image writing using the write light with wavelength λ2 is performed when the color illumination light with wavelength λ12 is incident on the read light valve, and an image writing using the write light with wavelength λ3 is performed when the color illumination light with wavelength λ13 is incident on the read light valve.
 13. The projection type video display according to claim 10 or 11, wherein there is further provided a polarization beam splitter and an optical member for introducing the image-writing light emitted from the write light valve to the read light valve and for introducing each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the polarization beam splitter, and the image-writing light is changed into the particular polarized light, and the image-writing light is returned to the polarization beam splitter, and the returned image-writing light is reflected on the polarization beam splitter and is introduced into the optical member after passing through the writing optical system.
 14. The projection type video display according to claim 10 or 11, wherein there is further provided an optical member for introducing the image-writing light emitted from the write light valve to the read light valve and for introducing each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the optical member and the writing optical system, and the image-writing light is introduced into the read light valve after passing through the writing optical system and the optical member.
 15. The projection type video display according to claim 10 or 11, wherein there is further provided an optical member for leading the image-writing light emitted from the write light valve to the read light valve and for leading each color image light emitted from the read light valve to the projection optical system, wherein the write light is introduced into the write light valve after passing through the optical member, and the image-writing light emitted from the write light valve introduced into the read light valve through the writing optical system after changing its optical path by the optical member, and each color image light is introduced into the projection optical system after passing through the writing optical system and the optical member, wherein an image formation plane of each color image light is formed between the projection optical system and the optical member.
 16. The projection type video display according to claim 10 or 11, wherein there is provided a shift device for shifting the write light valve or the writing optical system up-and-down and/or right-and-left in a plane perpendicular to an optical axis of the image writing.
 17. The projection type video display according to claim 10 or 11, wherein there is further provided a shift instruction operation portion which inputs a signal indicating a shift by an user operation, wherein the driver adjusts the position of the image for each color which is written into the write light valve based on the signal indicating the shift. 